Chapter 4 Types of Rocket Motor

1. Chapter 4Types of Rocket Motor

2. Types of Rocket Motor • Rocket motors can be classified into many types. • Rocket propulsion systems that have moving parts, for example pumps and turbines, are called engines. • Propulsion systems without moving parts are called motors.

3. Cold Gas • The cold gas motor is the simplest form of rocket propulsion • When thrust is needed a valve is opened. • The gas escapes through a nozzle where it is accelerated. • Cold gas motors are used in NASA’s Man Manoeuvring Unit (MMU)

4. Cold Gas Advantages Disadvantages Low thrust Very inefficient. • Cheap • Simple • Safe • Useful where small amounts of thrust are needed for short periods of time.

5. Monopropellant • Monopropellant engines use a single chemical that spontaneously ignites in the presence of a catalyst. • Some monopropellants can reach full operating temperature and pressure in 1/100 of a second or less, which makes them useful in applications where a short burst of thrust is required.

6. Monopropellant • Hydrogen peroxide and hydrazine are two common monopropellants. • Very pure hydrogen peroxide, sometimes referred to as high test peroxide (HTP), is very unstable. When it comes into contact with a platinum catalyst it spontaneously decomposes to water and oxygen, releasing a lot of heat and creating superheated steam and oxygen. • Hydrazine decomposes into ammonia, nitrogen and hydrogen at about 800ºC when it comes into contact with a platinum catalyst

7. Monopropellant Advantages Disadvantages Chemical can be very dangerous to manufacture, transport and store. • Simplicity • Relatively high specific impulse • Quick response • Easy to control

8. Bipropellant • Bi-propellant engines are a form of liquid propellant engine which require no ignition system. • They use two chemical reagents which spontaneously ignite as soon as they come into contact with each other and release a lot of heat. • Chemical reactions which spontaneously ignite are called hypergolic.

9. Bipropellant • Nitrogen tetroxide and hydrazine are useful reagents in bi-propellant engines. • They can be stored for long periods, are relatively light liquids, and react strongly. • Bi-propellant engines based on these two chemicals are commonly used in satellites and deep space probes.

10. Bipropellant Advantages Disadvantages The chemicals can be very dangerous to manufacture, transport and store. • Simple • Reliable • Well proven technology

11. Solid Motors • Solid propellant motors are the most common type of rocket motor • When the igniter fires it sets fire to the surface of the propellant. The hot gas from this combustion fills the hollow core of the motor and rushes out through the throat and nozzle. • The propellant burns outwards from the core to the case until it has all been consumed, often referred to as burn out.

12. Solid Motors • Solid propellant rocket motors are ideal for applications which require a predictable thrust for a fixed period of time. • Some common applications are: • missiles • launch vehicles • model rockets • safety systems • ejector seats • flares • fireworks

13. Solid Motors • The propellant fills a metal case which serves as a combustion chamber. • This motor is called a core burning motor as, after ignition, the hollow core of the motor burns outwards towards the walls of the case

14. Solid Motors • Solid propellants must contain both the propellant and the oxidiser • Common propellants are • Black powder • Ammonium perchlorate composite propellant (APCP)

15. Solid Motors • If we had a transparent case we would see the propellant burn from the core outwards • As the propellant burns from the core outwards, the burning surface area increases. The motor thus produces more gas per second. • As more gas is produced the mass flow rate increases, so the thrust increases with time. • This is called a progressive burn as thrust increases with time.

16. Solid Motors • Rocket motor designers design the shape of the propellant to give specific thrust profiles. • By changing the shape of the propellant inside the case it is possible to create motors with thrust profiles that • increase with time (progressive) • remain constant with time (neutral) • decrease with time (regressive).

17. Solid Motors Advantages Disadvantages Once ignited the propellant cannot be controlled or extinguished. • Easy to manufacture • Simple to use • Propellant is relatively safe to store and transport

18. Liquid & Gas Engines • Liquid & gas rocket engines are very complex. • Fuel and an oxidiser, usually liquid oxygen (LOX) are burned in a combustion chamber to generate very high temperature exhaust gases.

19. Liquid & Gas Engines • Engines which use liquid or gaseous fuels are very common in large rockets • They can be very efficient and have specific impulse up to 400 seconds. • They can have very high thrust.

20. Liquid & Gas Engines Advantages Disadvantages Extremely complex Difficult to design expensive to design and manufacture • High thrust is possible • Very efficient

21. Liquid & Gas Engines • Fuel and LOX are pumped into the combustion chamber at high pressure. • Specially designed injectors mix the fuel and LOX to ensure that all the fuel is burned

22. Liquid & Gas Engines • Some of the fuel and LOX are used to power a turbine which drives the pumps. • The waste gases from the turbine are at low temperature and are not used for propulsion.

23. Liquid & Gas Engines • Vulcain rocket engine from EADS • The injector assembly (A) sprays the fuels and LOX into the chamber to ensure that it is thoroughly mixed before combustion • The bottom of the combustion chamber and throat (B) are very precisely manufactured to ensure the smooth flow of gas through the throat • The combustion chamber is surrounded by the pumps, turbine and valves for feeding fuel and LOX to the injectors.

24. Liquid & Gas Engines • Vulcain rocket engine from EADS • This shows the injector at the top, combustion chamber and throat.

25. Liquid & Gas Engines • The exhaust gases in the combustion chamber, throat and nozzle achieve temperatures of over 2000C. • This is hot enough to melt the steel from which the walls of the engine are made. • The walls of the injector and combustion chamber are cooled by spraying a thin film of cool fuel on the walls of the chamber.

26. Liquid & Gas Engines • To prevent the throat and nozzle from melting cold, high pressure, fuel is pumped through narrow pipes to cool the steel. • This is called “regenerative cooling”

27. Liquid & Gas Engines • HM7 engine made by EADS • The picture on the left shows the motor assemble, including the exhaust from the turbine. • The picture on the right shows the fine mesh of cooling tubes for regenerative cooling of a nozzle. • Each tube has to be accurately positioned and perfectly welded to prevent a catastrophic leak of hot fuel.

28. Liquid & Gas Engines • Another technique for cooling the nozzle is to inject the used gases from the turbine. • These form a thin film of (relatively) cool gas between the nozzle walls and the exhaust gas, preventing the nozzle wall from melting. • This is called “film cooling”, sometimes called “curtain cooling”.

29. Liquid & Gas Engines • Some rocket engines use both regenerative cooling and curtain cooling. • The F-1 engine, used on the Saturn 5 rocket, used both regenerative and curtain cooling to protect its very long nozzle.

30. Liquid & Gas Engines • The F-1 rocket engine is the most powerful rocket engine ever built. • It was cooled using regenerative cooling in the upper nozzle and curtain cooling in the lower nozzle. • The regenerative cooling used a grid of pipes which surrounded the upper nozzle. • The gases for curtain cooling were introduced from the turbine exhaust, which was wrapped around the lower nozzle.

31. Liquid & Gas Engines • The fuel and oxidizer are stored in tanks inside the rocket body. • Tanks are pressurized with an inert gas to force the fuel and oxidizer towards the engine. • This arrangement is called a “blowdown” system. • “Inert” means that the gas will not chemically react with the fuel or oxidiser. • Helium is often used as the inert gas.

32. Liquid & Gas Engines • The fuel and propellant tanks are normally stacked one above the other. • The chemical from the upper tank needs to be fed to the motor. In some rockets the pipe it external to the rocket. • To save weight some rockets use one large tank which is divided by a bulkhead. The pipe from the upper tank is routed through the lower tank.

33. Hybrid Motors • Hybrid motors burn a solid propellant in a gaseous oxidiser. They are this a hybrid of a solid motor and a liquid/gas motor. • The valve lets the oxidiser into the combustion chamber where it is ignited. • The solid propellant will burn while the gas is flowing, but will stop when the valve closes.

34. Hybrid Motors • A hybrid motor uses a pressurised oxidiser in liquid or gaseous form and forces it through a solid propellant. • The propellant can be a conventional solid propellant, or any material that can burn at a high temperature and produce gas. • Plastics are commonly used as the propellant as they are intrinsically safe to manufacture and store. • LOX or Nitrous Oxide are commonly used as the gaseous oxidiser.

35. Hybrid Motors Advantages Disadvantages Some residual propellant is usually left Difficult to relight • Relatively simple construction • Low cost to build and operate • Materials are safe to manufacture and transport • Higher specific impulse than some solid propellant motors

36. Electric Propulsion • Ion thrusters use electric and magnetic fields to accelerate gas ions to very high velocity, typically 30 km per second • The momentum of the gas ions provides the thrust

37. Electric Propulsion • They are ideal as manoeuvring thrusters for satellites where low thrust and high efficiency are important. • Ion thrusters have a very low mass flow rate (m-dot) but the gas has a very high velocity (30 km/s). • Ion thrusters can only work in the vacuum of space. They do not work inside the atmosphere.

38. Electric Propulsion • RIT XT Ion Thruster made by EADS • This small thruster provides about 0.1 Newtons of thrust. It is designed to be used as a manoeuvring thruster for satellites. • It has a specific impulse better than 3000 seconds. • The thruster is about 20cm across

39. Electric Propulsion Advantages Disadvantages Low thrust Need a lot of electrical power Cannot work inside the atmosphere • Simple • Very high specific impulse • Light weight.

40. Nuclear Thermal • A light gas, ideally hydrogen, is pumped from a storage tank through a nuclear reactor. • The reactor heats the gas to a very high temperature, and it expands through a de-Laval nozzle.

41. Nuclear Thermal • Nuclear thermal engines have the potential to offer both high thrust and a specific impulse of over 1000. • There have been experiments to make nuclear thermal engines, starting with the NERVA programme in 1947, but these engines have yet to be used in a rocket. • The difficulties are not technical but political; no nation wants nuclear reactors flying over it’s territory.

42. Nuclear Thermal Advantages Disadvantages Unproven technology Political issues of launching nuclear reactors. • High thrust • High specific impulse.

43. Solar Thermal • Solar thermal propulsion focuses the sun’s rays on a small chamber through which gas is being pumped. • The gas is heated to a temperature of 2000ºC, which causes it to expand through a nozzle.

44. Solar Thermal • Solar thermal propulsion is a novel proposal for generating small thrusts for long durations with high efficiency. • It is suitable to gradually accelerate small objects in space. • The technology is currently unproven

45. Solar Thermal Advantages Disadvantages Power decreases as the motor gets further from the Sun The need for accurate pointing of the mirror This technology has yet to be tried in space. • Simple • Availability of limitless energy from the sun.

46. Comparison